Method and apparatus for plasma dicing a semi-conductor wafer

ABSTRACT

The present invention provides a method for plasma dicing a substrate. The substrate is provided with a top surface and a bottom surface, the top surface of the substrate having a plurality of street areas and at least one device structure. The substrate is placed onto a support film on a frame to form a work piece. A process chamber having a plasma source is provided. A work piece support is provided within the plasma process chamber. The work piece is placed onto the work piece support. A plasma is generated from the plasma source in the plasma process chamber. The work piece is processed using the generated plasma and a byproduct generated from the support film while the support film is exposed to the generated plasma.

CROSS REFERENCES TO RELATED APPLICATIONS

This utility patent application is a division of commonly owned U.S.Utility patent application Ser. No. 15/824,166 entitled: METHOD ANDAPPARATUS FOR PLASMA DICING A SEMI-CONDUCTOR WAFER filed Nov. 28, 2017,which was filed based on commonly owned U.S. Provisional PatentApplication Ser. No. 62/428,078 filed Nov. 30, 2016 entitled: METHOD ANDAPPARATUS FOR PLASMA DICING A SEMI-CONDUCTOR WAFER, these PatentApplications incorporated by reference herein.

FIELD OF THE INVENTION

The invention relates to the use of an apparatus for the formation ofindividual device chips from a semi-conductor wafer, and in particularto an apparatus which uses plasma etching to separate the wafer intoindividual die.

BACKGROUND

Semi-conductor devices are fabricated on substrates which are in theform of thin wafers. Silicon is commonly used as the substrate material,but other materials, such as III-V compounds (for example GaAs and InP)are also used. In some instances (for example, the manufacture of LED's)the substrate is a sapphire or silicon carbide wafer on which a thinlayer of a semi-conducting material is deposited. The diameter of suchsubstrates range from 2 inches and 3 inches up to 200 mm, 300 mm, and450 mm and many standards exist (e.g., SEMI) to describe such substratesizes.

Plasma etching equipment is used extensively in the processing of thesesubstrates to produce semi-conductor devices. Such equipment typicallyincludes a vacuum chamber fitted with a high density plasma source suchas Inductively Coupled Plasma (ICP) which is used to ensure high etchrates, necessary for cost-effective manufacturing. In order to removethe heat generated during the processing, the substrate is typicallyclamped to a temperature controlled support. A pressurized fluid,typically a gas such as Helium is maintained between the substrate andthe support to provide a thermal conductance path for heat transfer. Amechanical clamping mechanism, in which a downward force is applied tothe top side of the substrate, may be used, though this may causecontamination due to the contact between the clamp and the substrate.Work piece bowing may also occur when using a mechanical clamp, sincecontact is typically made at the edge of the work piece and apressurized fluid exerts a force on the back of the work piece. Morefrequently an electrostatic chuck (ESC) is used to provide the clampingforce.

Numerous gas chemistries appropriate to the material to be etched havebeen developed. These frequently employ a halogen (Fluorine, Chlorine,Bromine, or Iodine) or halogen-containing gas together with additionalgases added to improve the quality of the etch (for example, etchanisotropy, mask selectivity and etch uniformity). Fluorine containinggases, such as SF₆, F₂, ClF₃ and/or NF₃, can be used to etch silicon ata high rate. In particular, a process (Bosch or TDM) which alternates ahigh rate silicon etch step with a passivation step to control the etchsidewall, is commonly used to etch deep features into silicon. Chlorine,Iodine, and/or Bromine containing gases are commonly used to etch III-Vmaterials.

Plasma etching is not limited to semiconducting substrates and devices.The technique may be applied to any substrate type where a suitable gaschemistry to etch the substrate is available. Other substrate types mayinclude carbon containing substrates (including polymeric substrates),ceramic substrates (e.g., AlTiC and sapphire), metal substrates, glasssubstrates, and die attach films

To ensure consistent results, low breakage and ease of operation,robotic wafer handling is typically used in the manufacturing process.Handlers are designed to support the wafers with minimal contact, tominimize possible contamination and reduce the generation ofparticulates. Edge contact alone, or underside contact close to thewafer edge at only a few locations (typically within 3-6 mm of the waferedge), is generally employed. Handling schemes, which include wafercassettes, robotic arms and within process chamber fixtures includingthe wafer support and ESC, are designed to handle the standard wafersizes as noted previously.

After fabrication on the substrate, the individual devices (die orchips) are separated from each other prior to packaging or beingemployed in other electronic circuitry. For many years, mechanical meanshave been used to separate the die from each other. Such mechanicalmeans have included breaking the wafer along scribe lines aligned withthe substrate crystal axis or by using a high speed diamond saw to sawinto or through the substrate in a region (streets) between the die.More recently, lasers have been used to facilitate the scribing process.

Such mechanical wafer dicing techniques have limitations which affectthe cost effectiveness of this approach. Chipping and breakage along thedie edges can reduce the number of good die produced, and becomes moreproblematic as wafer thicknesses decrease. The area consumed by the sawbade (kerf) may be greater than 100 microns which is valuable area notuseable for die production. For wafers containing small die (e.g.,individual semiconductor devices with a die size of 500 microns by 500microns) this can represent a loss of greater than 20%. Further, forwafers with many small die and hence numerous streets, the dicing timeis increased, and productivity decreased, since each street is cutindividually. Mechanical means are also limited to separation alongstraight lines and the production of square or oblong shaped chips. Thismay not represent the underlying device topology (e.g., a high powerdiode is round) and so the rectilinear die format results in significantloss of useable substrate area. Laser dicing also has limitations byleaving residual material on the die surface or inducing stress into thedie.

It is important to note that both sawing and laser dicing techniques areessentially serial operations. Consequently, as device sizes decrease,the time to dice the wafer increases in proportion to the total dicingstreet length on the wafer.

Recently plasma etching techniques have been proposed as a means ofseparating die and overcoming some of these limitations. After devicefabrication, the substrate is masked with a suitable mask material,leaving open areas between the die. The masked substrate is thenprocessed using a reactive-gas plasma which etches the substratematerial exposed between the die. The plasma etching of the substratemay proceed partially or completely through the substrate. In the caseof a partial plasma etch, the die are separated by a subsequent cleavingstep, leaving the individual die separated. The technique offers anumber of benefits over mechanical dicing:

1) Breakage and chipping is reduced;

2) The kerf dimensions can be reduced to well below 20 microns;

3) Processing time does not increase significantly as the number of dieincreases;

4) Processing time is reduced for thinner wafers; and

5) Die topology is not limited to a rectilinear format.

After device fabrication, but prior to die separation, the substrate maybe thinned by mechanical grinding or similar process down to a thicknessof a few hundred microns, or even less than a hundred microns.

Prior to the dicing process, the substrate is typically mounted on adicing fixture. This fixture is typically comprised of a rigid framethat supports an adhesive membrane. The substrate to be diced is adheredto the membrane. This fixture holds the separated die for subsequentdownstream operations. Most tools used for wafer dicing (saws or laserbased tools) are designed to handle substrates in this configuration anda number of standard fixtures have been established; however, suchfixtures are very different from the substrates which they support.Though such fixtures are optimized for use in current wafer dicingequipment, they cannot be processed in equipment which has been designedto process standard substrates. Thus, current automated plasma etchingequipment is not suitable for processing substrates fixtured for dicingand it is difficult to realize the benefits that plasma etch techniquesshould have for die separation.

Therefore, what is needed is a plasma etching apparatus which can beused for dicing a semiconductor substrate into individual die and whichis compatible with the established wafer dicing technique of handling asubstrate mounted on tape and supported in a frame, and which is alsocompatible with standard front side masking techniques.

Nothing in the prior art provides the benefits attendant with thepresent invention. Therefore, it is an object of the present inventionto provide an improvement which overcomes the inadequacies of the priorart devices and which is a significant contribution to the advancementto the dicing of semiconductor substrates using a plasma etchingapparatus.

Another object of the present invention is to provide a method of dicinga substrate, the method comprising: providing a plasma process chamberhaving a plasma source; providing a work piece support within the plasmaprocess chamber; providing the substrate having a top surface and abottom surface, the top surface of the substrate having a plurality ofstreet areas and at least one device structure; placing the substrateonto a support film on a frame to form a work piece; placing the workpiece onto said work piece support; generating a plasma from the plasmasource in the plasma process chamber; and processing the work pieceusing the generated plasma and a byproduct generated from the supportfilm while the support film is exposed to the generated plasma.

Yet another object of the present invention is to provide a method ofdicing a substrate, the method comprising: providing a plasma processchamber having a plasma source; providing a work piece support withinthe plasma process chamber; providing the substrate having a top surfaceand a bottom surface, the top surface of the substrate having aplurality of street areas and at least one device structure; placing thesubstrate onto a support film on a frame to form a work piece; placingthe work piece onto said work piece support; generating a plasma fromthe plasma source in the plasma process chamber; etching a surface ofthe substrate of the work piece using the generated plasma to removedmaterial from the surface of the substrate and provide exposed surfaces;and depositing a passivation layer comprising a byproduct generated fromthe support film that is exposed to the generated plasma onto thesurfaces that were exposed in the etching step.

Still yet another object of the present invention is to provide a methodof dicing a substrate, the method comprising: providing a plasma processchamber having a plasma source; providing a work piece support withinthe plasma process chamber; providing the substrate having a top surfaceand a bottom surface, the top surface of the substrate having aplurality of street areas and at least one device structure; placing thesubstrate onto a support film on a frame to form a work piece; placingthe work piece onto said work piece support; generating a plasma fromthe plasma source in the plasma process chamber; and etching a surfaceof the substrate of the work piece using a plasma etch gas and abyproduct generated from the support film that is exposed to thegenerated plasma to removed material from the surface of the substrateand provide exposed surfaces.

The foregoing has outlined some of the pertinent objects of the presentinvention. These objects should be construed to be merely illustrativeof some of the more prominent features and applications of the intendedinvention. Many other beneficial results can be attained by applying thedisclosed invention in a different manner or modifying the inventionwithin the scope of the disclosure. Accordingly, other objects and afuller understanding of the invention may be had by referring to thesummary of the invention and the detailed description of the preferredembodiment in addition to the scope of the invention defined by theclaims taken in conjunction with the accompanying drawings.

SUMMARY OF THE INVENTION

The present invention describes a plasma processing apparatus whichallows for plasma dicing of a semiconductor substrate. After devicefabrication and wafer thinning, the front side (circuit side) of thesubstrate is masked using conventional masking techniques which protectsthe circuit components and leaves unprotected areas between the die. Thesubstrate is mounted on a thin tape which is supported within a rigidframe. The substrate/tape/frame assembly is transferred into a vacuumprocess chamber and exposed to reactive gas plasma where the unprotectedareas between the die are etched away. During this process, the frameand tape are protected from damage by the reactive gas plasma. Theprocessing leaves the die completely separated. After etching, thesubstrate/tape/frame assembly is additionally exposed to plasma whichremoves potentially damaging residues from the substrate surface. Aftertransfer of the substrate/tape/frame assembly out of the processchamber, the die are removed from the tape using well known techniquesand are then further processed (e.g., packaged) as necessary.

Another feature of the present invention is to provide a method forplasma dicing a substrate. The substrate can have a semiconducting layersuch as Silicon and/or the substrate can have a III-V layer such asGaAs. The substrate can have a protective layer such as a photoresistlayer that is patterned on a circuit side of the substrate. Thesubstrate is provided with a top surface and a bottom surface, the topsurface of the substrate having a plurality of street areas and at leastone device structure. The at least one of the plurality of streets ofthe substrate can intersect at an edge of the substrate. The substrateis placed onto a support film on a frame to form a work piece. Thesubstrate can be adhered to the support film. The support film canfurther comprise a carbon containing layer. The support film can furthercomprise a plurality of layers. The support film can further comprise anadhesive layer. The frame of the work piece can have a conductive layerand/or a metal layer. A process chamber having a plasma source isprovided. The plasma source can be a high density plasma source. A workpiece support is provided within the plasma process chamber. Anelectrostatic chuck can be incorporated into the work piece support. Thework piece is placed onto the work piece support. An RF power source canbe coupled to the work piece support to create a plasma around the workpiece. A thermal communication between the work piece and the work piecesupport can be provided by supplying a pressurized gas such as heliumfrom the work piece support to the work piece. A plasma is generatedfrom the plasma source in the plasma process chamber. The work piece isprocessed using the generated plasma and a byproduct generated from thesupport film while the support film is exposed to the generated plasma.The at least one device structure on the substrate can be protectedduring the processing step.

Yet another feature of the present invention is to provide a method forplasma dicing a substrate. The substrate can have a semiconducting layersuch as Silicon and/or the substrate can have a III-V layer such asGaAs. The substrate can have a protective layer such as a photoresistlayer that is patterned on a circuit side of the substrate. Thesubstrate is provided with a top surface and a bottom surface, the topsurface of the substrate having a plurality of street areas and at leastone device structure. The at least one of the plurality of streets ofthe substrate can intersect at an edge of the substrate. The substrateis placed onto a support film on a frame to form a work piece. Thesubstrate can be adhered to the support film. The support film canfurther comprise a carbon containing layer. The support film can furthercomprise a plurality of layers. The support film can further comprise anadhesive layer. The frame of the work piece can have a conductive layerand/or a metal layer. A process chamber having a plasma source isprovided. The plasma source can be a high density plasma source. A workpiece support is provided within the plasma process chamber. Anelectrostatic chuck can be incorporated into the work piece support. Thework piece is placed onto the work piece support. An RF power source canbe coupled to the work piece support to create a plasma around the workpiece. A thermal communication between the work piece and the work piecesupport can be provided by supplying a pressurized gas such as heliumfrom the work piece support to the work piece. A plasma is generatedfrom the plasma source in the plasma process chamber. A surface of thesubstrate of the work piece is etched using the generated plasma toremoved material from the surface of the substrate and provide exposedsurfaces. The etching step can be an anisotropic etch. A passivationlayer comprising a byproduct generated from the support film that isexposed to the generated plasma is deposited onto the surfaces that wereexposed in the etching step. The at least one device structure on thesubstrate can be protected during the etching step.

Still yet another feature of the present invention is to provide amethod for plasma dicing a substrate. The substrate can have asemiconducting layer such as Silicon and/or the substrate can have aIII-V compound semiconductor-containing layer such as GaAs. Thesubstrate can have a protective layer such as a photoresist layer thatis patterned on a circuit side of the substrate. The substrate isprovided with a top surface and a bottom surface, the top surface of thesubstrate having a plurality of street areas and at least one devicestructure. The at least one of the plurality of streets of the substratecan intersect at an edge of the substrate. The substrate is placed ontoa support film on a frame to form a work piece. The substrate can beadhered to the support film. The support film can further comprise acarbon containing layer. The support film can further comprise aplurality of layers. The support film can further comprise an adhesivelayer. The frame of the work piece can have a conductive layer and/or ametal layer. A process chamber having a plasma source is provided. Theplasma source can be a high density plasma source. A work piece supportis provided within the plasma process chamber. An electrostatic chuckcan be incorporated into the work piece support. The work piece isplaced onto the work piece support. An RF power source can be coupled tothe work piece support to create a plasma around the work piece. Athermal communication between the work piece and the work piece supportcan be provided by supplying a pressurized gas such as helium from thework piece support to the work piece. A plasma is generated from theplasma source in the plasma process chamber. A surface of the substrateof the work piece is etched using a plasma etch gas and a byproductgenerated from the support film that is exposed to the generated plasmato removed material from the surface of the substrate and provideexposed surfaces. The at least one device structure on the substrate canbe protected during the etching step.

The foregoing has outlined rather broadly the more pertinent andimportant features of the present invention in order that the detaileddescription of the invention that follows may be better understood sothat the present contribution to the art can be more fully appreciated.Additional features of the invention will be described hereinafter whichform the subject of the claims of the invention. It should beappreciated by those skilled in the art that the conception and thespecific embodiment disclosed may be readily utilized as a basis formodifying or designing other structures for carrying out the samepurposes of the present invention. It should also be realized by thoseskilled in the art that such equivalent constructions do not depart fromthe spirit and scope of the invention as set forth in the appendedclaims.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a top down view of a semiconductor substrate illustratingindividual devices separated by streets;

FIG. 2 is a cross-sectional view of a semiconductor substrateillustrating individual devices separated by streets;

FIG. 3 is a cross-sectional view of a semiconductor substrate mounted totape and a frame;

FIG. 4 is a cross-sectional view of a semiconductor substrate mounted totape and a frame being etched by a plasma process;

FIG. 5 is a cross-sectional view of separated semiconductor devicesmounted to tape and a frame;

FIG. 6 is a cross-sectional view of a vacuum processing chamber;

FIG. 7 is a cross-sectional of a wafer/frame in process position;

FIG. 8 is an enlarged cross-sectional view of a frame and a cover ringin a vacuum processing chamber;

FIG. 9 is a cross-sectional view of a section of the inside the chamberwith the cover ring mounted to a chamber wall;

FIG. 10 is a cross-sectional view of a section of the inside the chamberwith the cover ring mounted to an internal heat sink;

FIG. 11 is a top down view of a semiconductor substrate mounted to tapeand a frame supported by a transfer arm;

FIG. 12 is a cross-sectional view of a semiconductor substrate mountedto tape and a frame supported by a transfer arm;

FIG. 13 is a cross-sectional view of a wafer/frame in a transferposition;

FIG. 14 is a top view of a screen;

FIG. 15 is a top view of an electrostatic chuck according to the priorart;

FIG. 16 is a top view of a multi-zone electrostatic chuck according tothe prior art;

FIG. 17 is a top view of an electrostatic chuck according to oneembodiment of the present invention;

FIG. 18 is a cross-sectional view of a substrate on an electrostaticchuck according to the prior art;

FIG. 19 is a cross-sectional view of a work piece on an electrostaticchuck according to one embodiment of the present invention;

FIG. 20 is a cross-sectional view of an electrostatic chuck according toone embodiment of the present invention;

FIG. 21 is a cross-sectional view of an electrostatic chuck according toone embodiment of the present invention;

FIG. 22 is a top view of a work piece with multiple substrates accordingto one embodiment of the present invention;

FIGS. 23a-23c are cross sectional views of variations of mechanicalpartitions according to the present invention;

FIG. 24 is a cross sectional view of etched features according to oneembodiment of the present invention; and

FIG. 25 is a flowchart of one embodiment of the present invention.

Similar reference characters refer to similar parts throughout theseveral views of the drawings.

DETAILED DESCRIPTION OF THE INVENTION

A typical semiconductor substrate after device fabrication isillustrated in FIG. 1. The substrate (100) has on its surface a numberof areas containing device structures (110) separated by street areas(120) which allows for separation of the device structures intoindividual die. Although silicon is commonly used as a substratematerial, other materials chosen for their particular characteristicsare frequently employed. Such substrate materials include GalliumArsenide and other III-V materials or non-semi-conductor substrates onwhich a semi-conducting layer has been deposited. Further substratetypes may also include Silicon-On-Insulator (SOI) wafers andsemiconductor wafers mounted on carriers. While the example abovedescribes die separated by streets, aspects of the invention may bebeneficially applied to other pattern configurations on a substrateincluding substrates containing Gallium, substrates containing Indium,substrates containing Aluminum, substrates containing epitaxial layers,substrates containing carbon, substrates that are polymeric, substratescontaining a semiconductor and/or substrates containing multiplesemiconductors.

In the present invention, as is shown in a cross sectional view in FIG.2, the device structures (110) are then covered with a protectivematerial (200) while the street areas (120) remain unprotected. Thisprotective material (200) can be a photoresist, applied and patterned bywell-known techniques. Some devices, as a final process step are coatedwith a protective dielectric layer such as silicon dioxide or PSG whichis applied across the whole substrate. This can be selectively removedfrom the street areas (120) by patterning with photoresist and etchingthe dielectric material, as is well known in the industry. This leavesthe device structures (110) protected by the dielectric material and thesubstrate (100) substantially unprotected in the street areas (120).Note that in some cases test features to check the wafer quality may belocated in the street areas (120). Depending on the specific waferfabrication process flow, these test features may or may not beprotected during the wafer dicing process. Although the device patternillustrated shows oblong die, this is not necessary, and the individualdevice structures (110) may be any other shape, such as hexagons, asbest suits the optimum utilization of the substrate (100). It isimportant to note that while the previous example considers dielectricmaterials as the protective film, that the invention may be practicedwith a wide range of protective films including semi-conductive andconductive protective films. Furthermore, the protective layer canconsist of multiple materials. It is also important to note that someportion of the protective film may be an integral part of the finaldevice structure (e.g., a passivation dielectric, metal bonding pad,etc.). Furthermore, the present invention can also be beneficially usedwith bulk wafers without the necessity of having devices or devicestructures. One such example may be a semiconductor substrate (Silicon,III-V compounds, etc.), mounted on a carrier or not mounted, covered bya masking material defining the structures to be etched. The substratemay also contain at least one additional layer with different materialproperties, such as for example an insulating layer.

The substrate (100) may be thinned, typically by a grinding process,which reduces the substrate thickness to a few hundred microns to asthin as approximately 30 microns or less. As is shown in FIG. 3, thethinned substrate (100) is then adhered to a tape (300) which in turn ismounted in a rigid frame (310) to form a work piece (320). The frame istypically metal or plastic, though other frame materials are possible.The tape (300) is typically made from a carbon-containing polymermaterial, and may additionally have a thin conductive layer applied toits surface. The tape (300) provides support for the thinned substrate(100) which is otherwise too fragile to handle without breakage. Itshould be noted that the sequence of patterning, thinning and thenmounting is not critical and the steps may be adjusted to best fit theparticular devices and substrate and the processing equipment used. Itis important to note that while the previous example considers a workpiece (320) that is comprised of mounting a substrate (100) on anadhesive tape (300) which in turn is attached to a frame (310), that theinvention is not limited by the configuration of the wafer and carrier.The wafer carrier can be comprised a variety of materials. The carriersupports the substrate during the plasma dicing process. Furthermore,the wafer need not be attached to the carrier using an adhesive—anymethod that holds the wafer to the carrier and allows a means thermalcommunication of the substrate to the cathode is sufficient (e.g., anelectrostatically clamped carrier, a carrier with a mechanical clampingmechanism, etc.).

After mounting the substrate (100) with the tape (300) in the dicingframe (310), the work piece (320) is transferred into a vacuumprocessing chamber. Ideally, the transfer module is also under vacuumwhich allows the process chamber to remain at vacuum during transfer,reducing processing time and preventing exposure of the process chamberto atmosphere and possible contamination. As shown in FIG. 6, the vacuumprocessing chamber (600) is equipped with a gas inlet (610), a highdensity plasma source (620) to generate a high density plasma, such asan Inductively Coupled Plasma (ICP), a work piece support (630) tosupport the work piece (320), an RF power source (640) to couple RFpower to the work piece (320) through the work piece support (630) and avacuum pump (650) for pumping gas from the processing chamber (600).During processing, the unprotected areas (120) of substrate (100) areetched away using a reactive plasma etch process (400) as shown in FIG.4. This leaves the devices (110) separated into individual die (500) asshown in FIG. 5. In another embodiment of the invention, the unprotectedareas (120) of the substrate (100) are partially etched away using areactive plasma etch process (400). In this case, a downstreamoperation, such as a mechanical breaking operation, can be used tocomplete the die separation. These downstream methods are well known inthe art.

While the previous example describes the invention using a vacuumchamber in conjunction with a high density plasma (e.g., ECRs, ICP,helicon, and magnetically enhanced plasma sources), it is also possibleto etch the unprotected areas of the substrate using a wide range ofplasma processes. For example, one skilled in the art can imaginevariations of the invention using a low density plasma source in avacuum chamber or even the use of plasmas at or near atmosphericpressures.

When the work piece (substrate/tape/frame assembly) (320) is in theposition for plasma processing, the frame (310) can be protected fromexposure to the plasma (400). Exposure to the plasma (400) may causeheating of the frame (310) which in turn may cause local heating of themounting tape (300). At temperatures above approximately 100 degreesCelsius, the physical properties of the tape (300) and its adhesivecapability may deteriorate and it will no longer adhere to the frame(310). Additionally, exposure of the frame (310) to the reactive plasmagas may cause degradation of the frame (310). Since the frame (310) istypically re-used after wafer dicing, this may limit the useful lifetimeof a frame (310). Exposure of the frame (310) to the plasma (400) mayalso adversely affect the etch process: for example the frame materialmay react with the process gas, effectively reducing its concentrationin the plasma which may reduce the etch rate of the substrate material,thus increasing process time. To protect the frame (310), a protectivecover ring (660), as shown in FIGS. 6, 7 and 8, is positioned above theframe (310). In one embodiment, the cover ring (660) does not touch theframe (310) since contact with the frame (310) (which would occur duringtransfer into the process chamber (600)) may generate undesirableparticles.

In FIG. 8, dimension (800) represents the distance between the coverring (660) and the frame (310). This dimension can range from greaterthan approximately 0.1 mm to less than approximately 20 mm with anoptimal value of 4 mm. If the distance (800) is too large, plasma willcontact the frame (310) and the benefits of the cover ring (660) will belost.

In one embodiment the cover ring (660) is temperature controlled.Without cooling, the cover ring (660) temperature may increase due toexposure to the plasma and in turn heat the tape (300) and the frame(310) via thermal radiation, causing degradation as noted above. For thecase where the cover ring (660) is cooled, cooling of the cover ring(660) is accomplished by having it in direct contact with a cooled body,such as the wall of the process chamber (600) shown in FIG. 9 or a heatsink (1000) located within the process chamber (600) shown in FIG. 10.To ensure that heat is adequately removed from the cover ring (660) tothe heat sink (1000), the cover ring (660) should be made of a materialthat has good thermal conductivity. Such materials include many metals,for example Aluminum, but other thermally conductive materials, such asAluminum Nitride and other ceramics can be used. The choice of the coverring material is chosen to be compatible with the plasma process gasesused. While Aluminum is satisfactory for Fluorine based processes, analternate material, such as Aluminum Nitride, or the addition of aprotective coating, such as Aluminum Oxide may be necessary whenChlorine based processes are used. Operation temperature of the coverring (660) during plasma processing ranges from about 25 degrees Celsiusto about 350 degrees Celsius. Preferably the temperature of the coverring (660) is held in the range of 50 degrees Celsius to 90 degreesCelsius which minimizes thermal radiation to the tape (300) and theframe (310) and ensures that the tape (300) maintains its mechanicalintegrity. Alternatively, the cover ring (660) may be temperaturecontrolled by bringing the cover ring (660) into contact with atemperature controlled fluid. This fluid can be a liquid or gas. In thecase where the cover ring (660) temperature is controlled by a fluid,the cover ring (660) may contain a number of fluid channels tofacilitate heat transfer. These fluid channels can be internal to thecover ring (660), externally attached, or some combination of the two.

The work piece (substrate/tape/frame assembly) (320) is transferred bothinto and out of the process chamber (600) by a transfer arm (1100) thatsupports the frame (310) and substrate (100) so that they are maintainednearly coplanar as shown in FIGS. 11 and 12. The transfer arm (1100) maysupport both the tape (300) and the frame (310) or the frame (310)alone, but it is important that the assembly (320) not be supportedbeneath the substrate (100) area alone because of the fragile nature ofthinned substrates (100). The transfer arm (1100) has an alignmentfixture (1110) attached to it that aligns the frame (310) in arepeatable position before being transferred into the process chamber(600). The frame (310) can also be aligned by other techniqueswell-known in semiconductor processing (e.g., optical alignment). Thealignment can also be performed on the substrate (100) by suchwell-known techniques. It is important that the work piece(substrate/tape/frame assembly) (320) be aligned before placement withinthe process chamber (600) to avoid miss-processing as explained below.

In FIG. 8, the substrate-to-frame dimension (810) represents thedistance between the outer diameter of the substrate (100) and the innerdiameter of the frame (310). This may be 20 mm to 30 mm (e.g., DiscoCorporation dicing frame has an inner diameter of about 250 mm for 200mm substrates, so that the substrate-to-frame dimension (810) isnominally 25 mm). During mounting of the wafer (100) on the tape (300)within the frame (310), the deviation of wafer (100) placement may be asmuch as 2 mm so that the cover ring to substrate distance (820), whichis the distance between the substrate (100) outer diameter and the innerdiameter of the cover ring (660) can also vary from assembly to assemblyby up to 2 mm. If at some point the cover ring to substrate distance(820) is less than zero, the cover ring (660) will overlay the edge ofthe substrate (100). This area of the substrate will be shadowed andprevented from etching, which can prevent die separation and causeproblems in subsequent processing steps. It is preferred that the coverring (660) does not overlap the substrate (100). Alignment of thesubstrate/tape/frame assembly (320) prior to transfer is required toprevent such problems. Further, to additionally ensure that cover ringto substrate distance (820) is not less than zero, the cover ring innerdiameter should be greater than the diameter of the substrate (100). Itis preferred that the cover ring inner diameter be 5 mm greater than thesubstrate diameter (e.g., 205 mm cover ring inner diameter for 200 mmsubstrate). The cover ring overhang dimension (830) in FIG. 8 representsthe distance from the inner diameter of the cover ring (660) to theinner diameter of the frame (310). Alignment of the frame (310) prior totransfer into the process chamber (600) ensures that the cover ringoverhang dimension (830) remains essentially constant for the entirecircumference around the substrate (100) and that any portion of tape(300) that is not contacted by the Electrostatic chuck (ESC) (670) issubstantially shadowed from the plasma. In a preferred embodiment anytape (300) that is not in thermal contact with the ESC (670) isoverlapped by the cover ring (660).

When the work piece (e.g., substrate/tape/frame assembly) (320) istransferred into the process chamber (600), it is placed onto thelifting mechanism (680) and removed from the transfer arm (1100). Thereverse process occurs during transfer of the work piece (e.g.,substrate/tape/frame assembly) (320) out of the process chamber (600).The lifting mechanism (680) touches the frame (310) area and provides nopoint contact to the substrate (100). Point contact to the substrate(100) can cause damage to the substrate (100), particularly after dieseparation and unloading of the work piece (320), since the flexibilityof the tape (300) may cause the die to contact each other and damage tooccur. FIG. 13 shows the lifting mechanism (680) lifting the frame (310)from the underside; however, the frame (310) can also be removed fromthe transfer arm (1100) by contact with the top surface, bottom surface,outer diameter of the frame (310) or any combination of these using aclamping device. In order to have enough clearance to place the workpiece (320) on the work piece support (630) to process the substrate(100), the frame (310), the work piece support (630), and the cover ring(660) can move relative to each other. This can be accomplished bymoving the cover ring (660), the work piece support (630), or thelifting mechanism (680) or any combination of the three.

During plasma processing, heat is transferred to all of the surfaces theplasma touches including the substrate (100), tape (300), and frame(310). The cover ring (660) will minimize the heat transfer to areas ofthe tape (300) and the frame (310), but the substrate (100) must beexposed to the plasma (400) for processing.

The perforations (695) in the mechanical partition (690) can be arrangedin a number of ways. FIG. 14 shows a top view of a mechanical partition(690) with a pattern of perforations (695) that are uniformlydistributed in a rectilinear pattern. While FIG. 14 shows a rectilinearpattern of perforations (695), alternate configurations includinghexagonal, honeycomb or circular perforation patterns may be used. Thedimensions of the perforations (2600) may vary across the mechanicalpartition (690) (e.g., FIGS. 23b and 23c ).

In an alternate embodiment, the perforation pattern in the mechanicalpartition (690) may designed such that the spacing between perforations(2610) is variable (e.g., FIGS. 23b and 23c ). In yet anotherembodiment, the size and/or shape of the perforations may vary acrossthe mechanical partition (690). The mechanical partition (690) can havea perforation pattern such that both the perforation size (2600) andspacing (2610) vary across the partition.

FIG. 15 shows a top view of an electrostatic chuck as is known in theart. An ESC (670) will commonly have a sealing region or regions (1700)to confine the pressurized fluid between the ESC and the substrate (100)being clamped. The sealing regions (1700) are commonly employed near theperimeter of the ESC and around any features that would otherwise causethe pressurized fluid to leak and degrade the heat transfer. Some ESCsmake use of multiple concentric seal bands (1700) as shown in FIG. 16 togenerate discrete volumes or zones (1800, 1810) that allow independentcontrol of the fluid pressure within the respective zone. These ESCs arecommonly described as multi pressure zone ESCs. It is also possible thatthe pressure zones (1800, 1810) are not discrete and some of thepressurized fluid leaks between zones. Wide sealing regions (1700) aretypically not preferred. Typically, the thermal gradients across thework piece area which overlaps said wide sealing region may negativelyimpact some characteristic of the etch. On the contrary, if a sealingregion is not wide enough, the pressurized fluid may leak and heattransfer may degrade. As shown in FIG. 15, in the prior art the sealingregions or bands (1700) described above do not extend past the substrate(100) since doing so would expose the sealing surface of the seal band(1700) to potentially corrosive plasma gases that may decrease thelifetime of the ESC. FIG. 18 shows the cross sectional view of a rigidsubstrate (100) on an electrostatic chuck as is known in the art. Notethat the seal band (1700) is overlapped by the substrate (100).Furthermore, it is typical in the art to have the substrate (100) extendbeyond the edge of the sealing surface (1700) in order to accommodatefor any placement error during placement of the wafer on the ESC (670).It is also important to note that in the prior art that the lift pinholes (1720) and lift pins (2025) used to lift the substrate off the ESCare also located under the substrate (100)—inside or within theoutermost seal band (1700). Finally, ESCs known in the art have theclamping electrode(s) (2010) confined to the areas underneath thesubstrate (100). Therefore the clamping electrode (2010) is inside ofthe area defined by the outer seal band (1700)—both of which are insidethe wafer perimeter.

FIG. 19 shows a cross sectional view for one embodiment of the currentinvention.

When clamping a flexible work piece (e.g., a work piece (320) containingtape (300), etc.), it is preferable to have at least one clampingelectrode (2010) overlap the sealing region (1700) as depicted in FIG.19. This is particularly important when a flexible region of the workpiece overlaps the sealing region (1700). Overlap of the clampingelectrode (2010) with the flexible work piece (300) helps minimizeHelium gas leakage. Preferably this overlap (2200) is greater than 1 mmwide. The overlap (2200) can be along inside seal band perimeter, outerseal band perimeter, within the seal band, or some combination of thethree.

FIGS. 20 and 21 show the clamping electrode (2340) has no electricalinsulator interposed between the clamping electrode (2340) and thematerial to be clamped (2320). In the case where the ESCs clampingelectrode (2340) is exposed (not covered by an electrical insulator) andthe clamping electrode (2340) is at least in partial contact with thematerial to be clamped (2320), the bottom surface of the material to beclamped (2320) that is in contact with the ESC electrode (2340) must beelectrically insulating.

In the case where the work piece (320) contains more than one substrate(100) as shown in FIG. 22, it is preferred that the ESC (670) extendsbeyond the edge of at least one substrate (100)—preferably extendingbeyond the edges of all substrates (100). In order to confine thecooling gas (typically helium) behind the substrates, the tape (300)must form a sealing surface between the electrostatic chuck (670) andthe tape (300). This sealing surface is often called a seal band (1700).In one embodiment, the sealing surface (1700) is continuous and forms aregion that circumscribes all the substrates (100). In anotherembodiment, the sealing band (1700) may be discontinuous andcircumscribes at least one substrate. In yet another embodiment, eachsubstrate (100) is circumscribed by an individual seal band (1700). In afurther embodiment, the substrates (100) may overlay the sealing band(s)or alternatively, the sealing band(s) may lie outside the substrate(s)(100).

As shown in FIG. 24, when etching a substrate down to an interface,defined by the contact of two materials (e.g., 2720 and 2730 in FIG. 24)of different relative dielectric constants (e.g., silicon on insulator,SOI structures), problems with the etch associated with charging at theinterface, are well known. Such problems can be electrical or physicaland are commonly known as notching (e.g., see 2700 in FIG. 23),trenching, feature profile degradation. Interface examples where theseproblems typically occur are Silicon-on-Insulator (SOI), semiconductorsubstrate mounted on insulating carriers, semiconductor wafers (e.g.,GaAs, Si) mounted on tape, and substrates containing at least oneelectrically insulating layer. These problems are undesirable for deviceyield and performance. For example, when etching silicon using a timedivision multiplexed (e.g., TDM, DRIE or Bosch) process stopping on aninsulator (e.g., SiO₂) it is known in the art that undercut (ornotching) will occur at the silicon/insulator interface.

In any embodiment according to the present invention for a method forplasma dicing a substrate, the substrate is provided with a top surfaceand a bottom surface, the top surface of the substrate having aplurality of street areas and at least one device structure. The atleast one of the plurality of streets of the substrate can intersect atan edge of the substrate. At least one street can be disposed between atleast two devices. At least one street can surround the perimeter of atleast one die. At least one street can surround the perimeter of mostdie. The streets can be positioned between a process control monitor andthe device. There can be multiple devices on the substrate. The devicecan be on the front side of substrate or both sides of the substrate.

In any embodiment according to the present invention for a method forplasma dicing a substrate, the at least one device structure on thesubstrate can be protected during the processing step. The protectioncan be provided by a photoresist mask, a hardmask, a trilayer mask, alaser grooved (ablated) mask, a mechanically defined mask, a saw definedmask, a scribe defined mask, and/or a water soluble mask (Hogomax). Theprotection layer can be a part of the device structure such as devicepassivation layers, bonding pads, interlayer dielectrics and/or aback-metal layer. The protection can be achieved by a device structureand an applied mask layer(s).

In any embodiment according to the present invention for a method forplasma dicing a substrate, the substrate is placed onto a support filmon a frame to form a work piece. The substrate or multiple substratescan be adhered to the support film. The substrates can be of the samematerial or the substrates can be of a different material. Thesubstrates can be the same size or a different size. The substrates canbe the same thickness or a different thickness. The substrate can beadhered on the side opposite the devices or the substrate can be adheredto the device side facing the tape.

In any embodiment according to the present invention for a method forplasma dicing a substrate, the support film can further comprise acarbon containing layer, can be polymeric, can be elastic, can be dicingtape or grinding tape. The support film can further comprise a pluralityof layers. The support film can further comprise an adhesive layer. Theadhesive layer can further comprise an acrylic based adhesive, arubber-based adhesive, a UV release adhesive, and/or a thermal releaseadhesive. The adhesive layer can be between approximately 5-200 micronsthick. The support film may contain a base layer. The base layer canfurther comprise polyolefin, PVC (polyvinyl chloride), EVA (Ethylenevinyl acetate), Polyethylene, Polyester-PET (Polyethylene terephthalate)and/or polyimide. The support film may contain a release layer and/or ananti-static layer. The support film's composition can change as afunction of the support film's thickness. The support film can contain aregion with a graded composition (composition changes as a function offilm thickness in a non-discrete manner). The support film can bedesigned to withstand temperatures of approximately 60 degrees Celsiusor temperatures up to approximately 300 degrees Celsius.

In any embodiment according to the present invention for a method forplasma dicing a substrate, the frame of the work piece can have aconductive layer and/or a metal layer. The frame can be adhered to thesupport film. The support film can overlap the frame, the support filmcan completely overlap the frame and/or the support film may not extendpast the outer diameter of the frame. The frame can be rigid. The framecan be made of metal, hardened magnetic stainless, electro-polishedand/or a resin (e.g., Acrylonitrile butadiene styrene). The frame can beapproximately 1-5 mm thick. The substrate can be positioned so thatthere is no overlap of the substrate and the frame. The inner diameterof the frame can be greater than the outer diameter of the substrate.The substrate can be indexed to the frame translationally and/orrotationally. The outer diameter of the frame can contain index featuresand/or the inner diameter of the frame can contain index features. Thesubstrate and the frame can be concentric.

In any embodiment according to the present invention for a method forplasma dicing a substrate, a process chamber having a plasma source isprovided. The plasma source can be a high density plasma source. A workpiece support is provided within the plasma process chamber. Anelectrostatic chuck can be incorporated into the work piece support. Thework piece is placed onto the work piece support. An RF power source canbe coupled to the work piece support to create a plasma around the workpiece. A thermal communication between the work piece and the work piecesupport can be provided by supplying a pressurized gas such as heliumfrom the work piece support to the work piece.

In any embodiment according to the present invention for a method forplasma dicing a substrate, a plasma is generated from the plasma sourcein the plasma process chamber. The entire work piece can be exposed tothe generated plasma and/or the entire substrate can be exposed to thegenerated plasma. The exposure of the support film to the generatedplasma can modify the support film composition. The exposure of thesupport film to the generated plasma can deposit material onto thesupport film. The exposure of the support film to the generated plasmacan chemically modify the support film. The exposure of the support filmto the generated plasma can thin the support film. The exposure of thesupport film to the generated plasma can etch the support film.

In any embodiment according to the present invention for a method forplasma dicing a substrate, at least a portion of the support film thatis overlapped by the substrate is not exposed to the generated plasma. Aportion of the support film outside the perimeter of the substrate canbe exposed to the generated plasma. The support film outside theperimeter of the substrate can be exposed to the generated plasma. Aportion of the support film adjacent to the perimeter of the substratecan be exposed to the generated plasma. The support film adjacent to theperimeter of the substrate can be exposed to the generated plasma. Aportion of the support film overlapped by the workpiece support can beexposed to the plasma. The support film overlapped by the workpiecesupport can be exposed to the plasma. A portion of the support filmsurface not in contact with the work piece support can be exposed to theplasma. The support film that can be overlapped by the frame can beexposed to the generated plasma. The support film that can be overlappedby the frame may not be exposed to the generated plasma. A portion ofthe support film inside the inner diameter of the frame can be exposedto the generated plasma. The support film inside the inner diameter ofthe frame can be exposed to the generated plasma. A portion of thesupport film that is adjacent to the inner diameter of the frame can beexposed to the generated plasma. The support film that is adjacent tothe inner diameter of the frame can be exposed to the generated plasma.The support film can remain intact during the exposure to the generatedplasma. The support film can be suitable for an expansion operation postexposure to the generated plasma. The support film can be etched priorto the substrate being exposed to the generated plasma. The support filmcan be selectively etched faster than the substrate in a portion of theprocess. (e.g., the support film etch rate is greater than the substrateetch rate for at least a portion of the process). A layer of the supportfilm can be thinned prior to the substrate being exposed to thegenerated plasma.

In any embodiment according to the present invention for a method forplasma dicing a substrate, the possible change in the support filmcomposition can be detected during the exposure of the support film tothe generated plasma. The support film surface composition can bemonitored using radiation (e.g., light). The radiation can emitted froman external light source (e.g., laser or broad band light source). Theradiation can be emitted from the plasma. The support film compositioncan be detected by optical emission spectrometry (OES), laser emissionspectrometry (LES), optical emission interferometry (OEI). The processtime required to change the support film composition can bepredetermined. The possible change in the support film composition canchange the substrate etch rate. The possible change in the support filmcomposition can change the support film etch rate. The possible changein the support film composition can change the etch mask etch rate. Thepossible change in the support film composition can affect die sidewallprofile. The possible change in the support film composition canincrease etch anisotropy. The possible change in the support filmcomposition can maintain vertical die sidewalls.

In one embodiment according to the present invention, the work piece isprocessed using the generated plasma and a byproduct generated from thesupport film while the support film is exposed to the generated plasma.

In another embodiment according to the present invention, a surface ofthe substrate of the work piece is etched using the generated plasma toremoved material from the surface of the substrate and provide exposedsurfaces. The etching step can have some degree of anistropy. Theetching step can be anisotropic. A passivation layer comprising abyproduct generated from the support film that is exposed to thegenerated plasma is deposited onto the surfaces that were exposed in theetching step. A reaction byproduct from the support film can bedeposited on the substrate. A byproduct from the support film cancontribute to the anisotropy of an etched feature in the substrate. Abyproduct from the support film can be deposited on a feature sidewalletched into the substrate. The anisotropy of the etched feature in thesubstrate can be adjusted by adjusting the support film etch rate. Theetch rate of the support film can be changed during the course of theprocess in order to modify and/or maintain a desired etch featureprofile in the substrate. The etch rate of the support film can beadjusted by adjusting plasma process parameters. The etch rate of thesupport film may be adjusted nearly independently of the substrate etchrate. In a case where the substrate contains a compound semiconductor(e.g., Group III-V semiconductors including GaAs, InP, AlGaAs, etc.) thesupport film etch rate can be adjusted by adjusting the RF bias appliedto the work piece. For example, when etching GaAs in achlorine-containing process, increasing the RF bias on the work piecesignificantly increases the support film etch rate with only a modesteffect on the GaAs etch rate. The etch rate of GaAs for plasma dicingcan be from tenths of microns per minute to over 50 microns per minute.The support film etch rates typically range from 0.01 micron per minuteto tens of microns per minute. The selectivity of GaAs:support film(ratio of etch rate of GaAs to etch rate of support film) can range fromnear 1:1 up to approximately 100:1. Typical etch rate selectivities ofGaAs to support film can be near 10:1. Decreasing the GaAs:support filmetch selectivity typically provides more sidewall passivation tofeatures etched into a GaAs substrate. In other words, lowering theGaAs:support film selectivity can increase the anisotropy of the GaAsetch. In another embodiment, a change in the composition of the supportfilm may effect the etch performance on the substrate. A change insupport film composition may effect the etch rate of the substratematerial. A change in support film composition may affect the degree ofanisotropy of features etched into the substrate. In a case where thesupport film consists of more than one layer, it can be beneficial tomodify the etch process in response to a change in the support filmcomposition. For example, when plasma dicing a GaAs-containing substrateon a support film it can be beneficial to modify the plasma processconditions based on the support film composition. GaAs can be etchedusing chlorine containing processes. Processes can contain Cl₂ as achlorine source and may contain additives to help with etch anisotropyor surface topology (e.g., surface roughness). Typical additives includehydrogen-containing gases (e.g., H₂, HCl, HBr, HI, CH₄, etc.),nitrogen-containing gases (e.g., N₂ and NH₄, etc.), boron containinggases (e.g., BCl₃, BF₃, BBr₃, etc.), silicon containing gases (e.g.,SiCl₄, etc.), carbon containing gases (e.g., CCl₄, CHCl₃,C_(x)H_(y)Cl_(z), etc.), or inert gases (Ar, He, Kr, Xe, etc.), andoxygen-containing gases (e.g., O₂, N₂O, CO, CO₂, H₂O, NO₂, SO₂, etc.).The inventors have observed that while etching a GaAs containingsubstrate on a support film (e.g., dicing tape that contains an acryliccontaining adhesive layer over a film base layer) using achorine-containing plasma etch process (e.g., BCl₃/Cl₂ based process)that the GaAs etch rate decreases dramatically once a portion of theadhesive layer of the support film has been consumed by the plasma. Theetch rate of the GaAs substrate decreases as a portion of the base layerof the film is exposed to the plasma. The base layer of the film cancontain polyethylene terephthalate (PET). The depletion of the adhesivelayer during a plasma process can be detected using optical emissionspectrometry. As the adhesive layer of the dicing tape is depleted, adecrease in the GaAs etch rate can be mitigated by increasing theconcentration (e.g., flow rate) of an oxygen-containing process gas.Increasing the concentration of an oxygen-containing process gas canincrease the GaAs etch rate. In a preferred embodiment, theoxygen-containing gas is injected into the plasma chamber using a gasinjector that is separate from the gas introduction used for anotherprocess gas. In a preferred embodiment, the oxygen containing gas isintroduced into the plasma chamber independently from a boron-containingprocess gas (e.g., BCl₃). In another preferred embodiment, the oxygencontaining gas is introduced into the plasma chamber independently fromthe a silicon-containing process gas (e.g., SiCl₄).

A general form of this embodiment is illustrated in FIG. 25. A plasmaprocess is initiated on a workpiece (e.g., at least one substratemounted on a support film with a frame), the condition of the supportfilm is monitored during the plasma process (e.g., by monitoring theemission intensity of the plasma at least one wavelength. In a preferredembodiment, the wavelength can be associated with an oxygen-containingmolecule), detecting a change in the condition of the support filmduring the plasma process (e.g., depletion of an adhesive layer in thefilm exposing a base layer), modifying at least one plasma parameter inresponse to the detected change in the support film condition (e.g.,changing the composition of the process feed gas. In a preferredembodiment increasing the concentration of at least oneoxygen-containing process gas) and continuing the plasma process.

In another embodiment according to the present invention a surface ofthe substrate of the work piece is etched using a plasma etch gas and abyproduct generated from the support film that is exposed to thegenerated plasma to removed material from the surface of the substrateand provide exposed substrate surfaces.

The present disclosure includes that contained in the appended claims,as well as that of the foregoing description. Although this inventionhas been described in its preferred form with a certain degree ofparticularity, it is understood that the present disclosure of thepreferred form has been made only by way of example and that numerouschanges in the details of construction and the combination andarrangement of parts may be resorted to without departing from thespirit and scope of the invention.

Now that the invention has been described,

What is claimed is:
 1. A method of dicing a substrate, the methodcomprising: providing a plasma process chamber having a plasma source;providing a work piece support within the plasma process chamber;providing the substrate; placing the substrate onto a support film on aframe to form a work piece; placing the work piece onto said work piecesupport; generating a plasma from the plasma source in the plasmaprocess chamber; exposing at least a portion of the support film that isnot overlapped by the substrate to the generated plasma; generating abyproduct from the exposed portion of the support film; and processingthe work piece using the generated plasma and the byproduct generatedfrom the exposed portion of the support film.
 2. The method according toclaim 1 wherein the substrate further comprising a compoundsemiconductor.
 3. The method according to claim 1 further comprisingmonitoring a change in a composition of the support film during theexposure of the support film to the generated plasma.
 4. The methodaccording to claim 3 further comprising modifying the processing of thework piece based on the composition of the support film.
 5. The methodaccording to claim 1 wherein the substrate is adhered to the supportfilm.
 6. The method according to claim 5 wherein the support filmfurther comprising a carbon containing layer.
 7. The method according toclaim 1 wherein the support film further comprising a plurality oflayers.
 8. The method according to claim 7 wherein the support filmfurther comprising an adhesive layer.
 9. A method of dicing a substrate,the method comprising: providing a plasma process chamber having aplasma source; providing a work piece support within the plasma processchamber; providing the substrate; placing the substrate onto a supportfilm on a frame to form a work piece; placing the work piece onto saidwork piece support; generating a plasma from the plasma source in theplasma process chamber; exposing at least a portion of the support filmthat is not overlapped by the substrate to the generated plasma;generating a byproduct from the exposed portion of the support film;etching a surface of the substrate of the work piece using the generatedplasma to remove material from the surface of the substrate and provideexposed surfaces; and depositing a passivation layer comprising thebyproduct generated from the support film that is exposed to thegenerated plasma onto the surfaces that were exposed in the etchingstep.
 10. The method according to claim 9 wherein the etch step is ananisotropic etch.
 11. The method according to claim 9 wherein thesubstrate further comprising a compound semiconductor.
 12. The methodaccording to claim 9 further comprising monitoring a change in acomposition of the support film during the exposure of the support filmto the generated plasma.
 13. The method according to claim 12 furthercomprising modifying the processing of the work piece based on thecomposition of the support film.
 14. The method according to claim 9wherein the substrate is adhered to the support film.
 15. The methodaccording to claim 14 wherein the support film further comprising acarbon containing layer.
 16. The method according to claim 9 wherein thesupport film further comprising a plurality of layers.
 17. The methodaccording to claim 16 wherein the support film further comprising anadhesive layer.
 18. A method of dicing a substrate, the methodcomprising: providing a plasma process chamber having a plasma source;providing a work piece support within the plasma process chamber;providing the substrate; placing the substrate onto a support film on aframe to form a work piece; placing the work piece onto said work piecesupport; generating a plasma from the plasma source in the plasmaprocess chamber; exposing at least a portion of the support film that isnot overlapped by the substrate to the generated plasma; generating abyproduct from the exposed portion of the support film; and etching asurface of the substrate of the work piece using a plasma etch gas andthe byproduct generated from the support film that is exposed to thegenerated plasma to remove material from the surface of the substrateand provide exposed surfaces.
 19. The method according to claim 18wherein the substrate further comprising a compound semiconductor. 20.The method according to claim 18 further comprising monitoring a changein a composition of the support film during the exposure of the supportfilm to the generated plasma.
 21. The method according to claim 18wherein further comprising modifying the processing of the work piecebased on the composition of the support film.
 22. The method accordingto claim 18 wherein the substrate is adhered to the support film. 23.The method according to claim 22 wherein the support film furthercomprising a carbon containing layer.
 24. The method according to claim18 wherein the support film further comprising a plurality of layers.25. The method according to claim 24 wherein the support film furthercomprising an adhesive layer.
 26. A method of dicing a substrate, themethod comprising: providing a plasma process chamber having a plasmasource; providing a work piece support within the plasma processchamber; providing the substrate; placing the substrate onto a supportfilm on a frame to form a work piece; placing the work piece onto saidwork piece support; generating a plasma from the plasma source in theplasma process chamber; exposing at least a portion of the support filmthat is not overlapped by the substrate to the generated plasma;processing the work piece using the generated plasma; monitoring asupport film composition during the processing step; detecting a changein the support film composition during the processing step; andmodifying the work piece processing step based on the detection step.